JP7177332B2 - Conveyor - Google Patents

Description

The present invention relates to a conveying device for conveying a workpiece in, for example, a semiconductor manufacturing apparatus, a liquid crystal substrate manufacturing apparatus, or the like.

2. Description of the Related Art Conventionally, in a semiconductor manufacturing apparatus, a liquid crystal substrate manufacturing apparatus, and the like, there is known a transfer robot apparatus in which an arm linearly moves a hand member for placing a wafer as an object to be transferred in the horizontal direction.

As shown in FIGS. 1 and 2 of Patent Document 1, a conventional transfer robot device has a swivel base 11 and a second outer link 14 connected by a pair of first intermediate links 12 and 13. A first parallel four-bar link 15 is formed by connecting the second link 14 and a hand link 18 with a pair of second intermediate links 16 and 17 to form a second parallel four-bar link 19. . The first intermediate links 12, 13 and the second intermediate links 16, 17 are formed to have the same link length, and the swivel base 11 and the first intermediate links 12, 13 are separated in the Y direction by the first intermediate links. It is pivotally supported around the fulcrum O1 and the second fulcrum O2. The first intermediate links 12, 13 and the second link 14 are pivotally supported around the third fulcrum O3, and the second intermediate links 16, 17 and the second link 14 are pivotally supported around the fourth fulcrum O4. It is A rotation transmission mechanism 20 is arranged between the first and second intermediate links.

Therefore, when the first rotating shaft 2 and the first intermediate link 13 are rotated clockwise about the first fulcrum O1, the first parallel four-bar link 15 rotates between the first fulcrum O1 and the second fulcrum O2. is a fulcrum and moves parallel to the Y1 direction. In this case, the first intermediate link 13 is rotated clockwise with respect to the second link 14 about the third fulcrum O3. As a result, the second intermediate link 16 is rotated counterclockwise about the fourth fulcrum O4 with respect to the second link 14 via the rotation transmission mechanism 20, and the second parallel four-bar link 19 is rotated to the second link 14. 4 moves in parallel in the Y1 direction with the fulcrum O4 as the fulcrum.

As illustrated in FIG. 10 of Patent Document 1, in the transfer robot device, the rotation transmission mechanism 20 is arranged between the first intermediate link 12 and the second intermediate link 17, and the first intermediate link 12 and the second intermediate link 17. It is arranged between the intermediate link 13 and the second intermediate link 16 . That is, between the pulley 20D coaxially fixed to the third fulcrum O3 of the first intermediate link 12 and the pulley 20C coaxially fixed to the fourth fulcrum O4 of the second intermediate link 17, the belt 20E is stretched. Between the pulley 20D coaxially fixed to the third fulcrum O3 of the first intermediate link 13 and the pulley 20C coaxially fixed to the fourth fulcrum O4 of the second intermediate link 16, a belt 20E is stretched.

Patent No. 3806812 specification

In the transfer robot device of Patent Document 1, since the pulley 20C connected to the second intermediate links 16 and 17 of the second parallel four-bar link 19 is in a released state, the belt 20E rotates in the loosening direction, and the belt 20E The tension of the In addition, in the transfer robot device of Patent Document 1, when the rotation transmission mechanism 20 is assembled to the second link 14, the tension adjustment of the belt 20E and the trajectory adjustment of the arm are performed at the same time while the operation of attaching the pulley 20C and the like is performed. There is a need to do. Therefore, assembly and adjustment are difficult, and productivity is very poor. Even if the belt 20E tension adjustment and arm trajectory adjustment are performed at the same time, the stability of the belt tension and the accuracy of the parallelism of the arm are poor. need to be improved.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a conveying apparatus capable of stabilizing the belt tension and improving the accuracy of arm parallelism.

In order to solve this problem, the present invention takes the following measures.
That is, in the conveying apparatus according to the present invention, the base ends of the pair of first links having the same length are rotatably connected to the first link base, and the tip ends of the pair of first links are connected to the intermediate link. A first parallel four-bar link mechanism that is rotatably connected to a table and in which one of the pair of first links is rotationally driven by a driving means , and a pair of second links of the same length whose base ends are connected to the intermediate A second parallel four-bar link mechanism that is rotatably connected to the link base and in which the distal ends of the pair of second links are rotatably connected to the second link base, and is disposed on the intermediate link base, A pair of first pulleys connected to each of the pair of first links, a second pulley connected to one of the pair of second links, and a pair of first pulleys on both sides of the second pulley. A belt transmission mechanism having a belt stretched so as to be arranged and transmitting a rotational driving force so that the first link and the second link rotate in opposite directions to each other. do.

Thus, in the conveying device according to the present invention, the belt is stretched so that the pair of first pulleys are arranged on both sides of one of the pair of second pulleys, thereby one of the pair of second pulleys is in the released state. Even in such a case, the rotation of the belt is restricted by fixing the belt to the pair of first pulleys. Therefore, it is possible to prevent one of the pair of second pulleys in the released state from rotating in the loosening direction and lowering the tension of the belt, thereby improving the stability of the belt tension.

The conveying apparatus according to the present invention is characterized in that the belt transmission mechanism has tension adjusting means for adjusting the tension of the belt.

As a result, in the conveying apparatus according to the present invention, when the belt transmission mechanism is assembled to the intermediate link base, the tension adjustment of the belt and the trajectory adjustment of the arm can be performed separately, making it easy to install pulleys and the like. As a result, the productivity is improved, and the stability of the belt tension and the accuracy of the arm parallelism are improved.

The conveying apparatus according to the present invention is characterized in that the tension adjusting means has a pressing member configured to be movable with respect to the intermediate link base so as to change the pressing force applied to the belt.

Thereby, in the conveying apparatus according to the present invention, the tension adjusting means can be easily constructed.

The conveying device according to the present invention is characterized in that the tension adjusting means has only one pressing member.

Thus, in the conveying device according to the present invention, the tension of the belt can be adjusted by pressing the belt only at one point.

In the conveying device according to the present invention, the pressing member is a driven roller configured to be rotatable as the belt moves.

As a result, in the conveying device according to the present invention, the pressing member is a driven roller that rotates as the belt moves. is reduced and the tension in the belt is evened out on both sides of the pressing member.

In the conveying apparatus according to the present invention, the belt transmission mechanism has rotation limiting means for limiting a range in which the other of the pair of second links can rotate with respect to the intermediate link base.

Thus, in the conveying device according to the present invention, the belt can be prevented from breaking by limiting the range in which the other of the pair of second links can rotate with respect to the intermediate link table.

As described above, according to the present invention, it is possible to provide a conveying apparatus capable of stabilizing the belt tension and improving the accuracy of the arm parallelism.

1 is a perspective view of a conveying device according to a first embodiment of the present invention; FIG. FIG. 2 is a plan view of the conveying device of FIG. 1; 2 is a front view of the conveying device of FIG. 1; FIG. FIG. 2 is a plan view showing a state in which the conveying device in FIG. 1 performs linear conveying; FIG. 2 is a plan view showing a belt transmission mechanism of the conveying device of FIG. 1; FIG. 8 is a plan view showing a belt transmission mechanism of a conveying device according to a second embodiment of the invention; FIG. 11 is a plan view showing a belt transmission mechanism of a conveying device according to a third embodiment of the present invention; FIG. 11 is a plan view showing a belt transmission mechanism of a conveying device according to a fourth embodiment of the present invention;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
As shown in FIGS. 1 to 4, the transport device 1 is a two-arm type transport device having two transport units 11a and 11b having the same basic configuration. For example, wafers, which are objects to be transferred, are linearly transferred on both sides of A. Therefore, in the following description, only the transport unit 11a will be described, and the description of the transport unit 11b will be omitted.

In the conveying unit 11a, a first link mechanism LD1 as a first parallel four-bar link mechanism of the present invention and a second link mechanism LD2 as a second parallel four-bar link mechanism of the present invention are connected via a belt transmission mechanism D. It is a configuration that is connected by In the first link mechanism LD1, base ends of a pair of first links L1a and L1b having the same length are rotatably connected to a fixed table A via a pair of first connecting shafts S1a and S1b. The tip portions of the links L1a and L1b are rotatably connected to an intermediate link base E via a pair of intermediate connecting shafts S3a and S3b.

The first connecting shaft S1a is rotatably supported by the fixed table A, and the first connecting shaft S1a and the first link L1a are integrally connected. The first connecting shaft S1b doubles as a driving shaft S0 that is driven by a driving means (not shown). The shaft S1b) and the first link L1b are integrally connected. The third connecting shaft S3a is rotatably supported by the intermediate link base E, and the third connecting shaft S3a and the first link L1a are integrally connected. The third connecting shaft S3b is rotatably supported by the intermediate link base E, and the third connecting shaft S3b and the first link L1b are integrally connected. The first connecting shaft S1a is connected to a rotating shaft S1c (not shown) arranged coaxially with the first connecting shaft S1b. When the rotating shaft S1c rotates, the first connecting shaft S1a rotates around the rotating shaft S1c (first connecting shaft S1b), and the fixed table A rotates. Therefore, when expanding and contracting the arm, the rotating shaft S1c is fixed and only the first connecting shaft S1b is rotationally driven. On the other hand, when the first connecting shaft S1b and the rotating shaft S1c are synchronized and rotated at the same time, the stationary base A rotates and the extension/retraction direction of the arm changes. As described above, in the conveying apparatus 1, only the arm can be extended and retracted, and the stationary table A can be rotated and the arm can be extended and retracted in parallel.

The second link mechanism LD2 includes a pair of second links L2a and L2b having the same length, and base ends of which are rotatably connected to an intermediate link base E via a pair of intermediate connecting shafts S4a and S4b. The tip portions of the links L2a and L2b are rotatably connected to the tip link plate C via a pair of second connecting shafts S2a and S2b. A wafer mounting table C1 is provided on the upper surface of the tip link plate C. As shown in FIG.

The intermediate connecting shaft S4a is rotatably supported by the intermediate link base E, and the intermediate connecting shaft S4a and the second link L2a are integrally connected. The intermediate connecting shaft S4b is rotatably supported by the intermediate link base E, and the intermediate connecting shaft S4b and the second link L2b are integrally connected. The second connecting shaft S2a is rotatably supported by the tip link plate C, and the second connecting shaft S2a and the second link L2a are integrally connected. The second connecting shaft S2b is rotatably supported by the tip link plate C, and the second connecting shaft S2b and the second link L2b are integrally connected.

Next, a description will be given of the belt transmission mechanism D that operates the second link mechanism LD2 when the first link mechanism LD1 performs parallel link motion by rotationally driving the first connecting shaft S1b, which is the drive shaft S0.

The belt transmission mechanism D is, as shown in FIG. and The pulley body P1a is integrally connected to a third connecting shaft S3a connected to the distal end of the first link L1a, and the pulley body P1b is integrally connected to the third connecting shaft S3b connected to the distal end of the first link L1b. , and the pulley body P2a is integrally connected to a fourth connecting shaft S4a connected to the tip of the second link L2a.

The interval between the pair of intermediate connecting shafts S3a and S3b of the intermediate link base E is the same as the interval between the pair of first connecting shafts S1a and S1b of the fixed base A, and the pair of intermediate connecting shafts S4a and S4b of the intermediate link base E is the same. is the same as the interval between the pair of second connecting shafts S2a and S2b of the tip link plate C. As shown in FIG.

In the belt transmission mechanism D, a belt T is stretched around the outer peripheral surfaces of the pulley bodies P1a, P2a, and P1b. The belt T is, for example, a steel belt, and is stretched along the lower side of the outer peripheral surface of the pulley body P1a and then along the upper side of the outer peripheral surface of the pulley body P2a in FIG. After that, the belt T is stretched along the outer peripheral surface of the pressing member P3 and then along the lower side of the outer peripheral surface of the pulley body P1b. Both ends of the belt T are fixed to the outer peripheral portions of the pulley bodies P1a and P1b via a plurality of bolts (not shown).

The pressing member P3 is integrally connected to a shaft S5a rotatably supported by the intermediate link base E, and is composed of a driven roller rotatable as the belt T moves. The pressing member P3 presses the belt T diagonally to the lower left in FIG. 5, and adjusts the tension of the belt T between the pulley bodies P2a and P1b. Therefore, the pressing member P3 is configured to be movable with respect to the intermediate link table E together with the shaft S5a, and to be fixed to the intermediate link table E together with the shaft S5a while the belt T is being pressed. In this manner, the pressing member P3 adjusts the tension of the belt T stretched over the pulley bodies P1a, P1b, and P2a by moving with respect to the intermediate link base E so as to change the pressing force applied to the belt T. It is configured as tension adjusting means DT. In this embodiment, the tension adjusting means DT has only one pressing member P3.

Therefore, in the belt transmission mechanism D, when the pulley body P1b connected to the drive shaft S0 (first connecting shaft S1b) via the first link L1b rotates, the tension is adjusted by the tension adjusting means DT (pressing member P3). Through the belt T, the torque of the pulley body P1b is transmitted to the pulley bodies P2a and P1a.

For example, when the pulley body P1b rotates counterclockwise in plan view, the pulley body P2a rotates clockwise in plan view, and the pulley body P1a rotates counterclockwise in plan view. That is, the pulley body P1a to which the first link L1a of the first link mechanism LD1 is connected and the pulley body P2a to which the second link L2a of the second link mechanism LD2 is connected rotate in opposite directions.

Therefore, when the pulley body P1b rotates, the pulley bodies P1a and P1b rotate in a predetermined direction, and the first links L1a and L1b rotate with respect to the intermediate link base E. Accordingly, the pulley body P2a rotates in a direction opposite to the predetermined direction, and the second links L2a and L2b rotate with respect to the intermediate link base E. That is, the belt T rotates the first links L1a and L1b of the first link mechanism LD1 in a predetermined direction with respect to the intermediate link base E, and rotates the pair of second links L2a and L2b of the second link mechanism LD2 to the intermediate links. The table E is rotated in a direction opposite to the predetermined direction.

In this embodiment, when the drive shaft S0 is rotationally driven (when the rotational shaft S1c is fixed and only the first connection shaft S1b is driven), the first connection shaft S1b, which is the drive shaft S0, is rotationally driven on the fixed base A. As shown in FIG. 4, when the first link L1b of the first link mechanism LD1 rotates counterclockwise with respect to the fixed table A in plan view, the counterclockwise rotational force of the pulley body P1b is applied to the belt T. is transmitted to the pulley bodies P2a and P1a by , the pulley body P2a rotates clockwise and the pulley body P1a rotates counterclockwise. Therefore, the first links L1a and L1b of the first link mechanism LD1 rotate counterclockwise with respect to the intermediate link base E in a plan view, and the second links L2a and L2b of the second link mechanism LD2 rotate toward the intermediate link base E. rotates clockwise in plan view. Conversely, when the first link L1a of the first link mechanism LD1 rotates clockwise in plan view with respect to the fixed base A, the clockwise rotational force of the pulley body P1b is transmitted by the belt T to the pulley bodies P2a and P1a. As a result, the pulley body P2a rotates counterclockwise and the pulley body P1a rotates clockwise. Therefore, the first links L1a and L1b of the first link mechanism LD1 rotate clockwise with respect to the intermediate link base E in plan view, and the second links L2a and L2b of the second link mechanism LD2 rotate to the intermediate link base E. On the other hand, it rotates counterclockwise in plan view.

That is, in the conveying device 1 of the present embodiment, the base ends of the pair of first links L1a and L1b having the same length are rotatably connected to the fixed table A, and the pair of first links L1a and L1b are connected to each other. A first parallel four-bar link mechanism LD1 whose distal end is rotatably connected to the intermediate link base E, and a pair of second links L2a and L2b of the same length, whose proximal ends are rotatably connected to the intermediate link base E. A second parallel four-bar link mechanism LD2 in which the tips of the pair of second links L2a and L2b are rotatably connected to the tip link plate C, and an intermediate link base E are arranged on the pair of first It has pulley bodies P1a and P1b respectively connected to the links L1a and L1b, a pulley body P2a connected to the second link L2a, and a belt T stretched between the pulley bodies P1a and P1b and the pulley body P2a. and a belt transmission mechanism D that transmits rotational driving force so that the first links L1a, L1b and the second links L2a, L2b rotate in opposite directions.

With this configuration, in the conveying device 1 of the present embodiment, the belt T is stretched so that the pulley bodies P1a and P1b are arranged on both sides of the pulley body P2a, so that the pulley body P2a is released. Even so, the rotation of the belt T is restricted by fixing the belt T to the pulley bodies P1a and P1b. Therefore, it is possible to prevent the pulley body P2a in the released state from rotating in the loosening direction and lowering the tension of the belt T, thereby improving the stability of the belt tension.

In the conveying device 1 of this embodiment, the belt transmission mechanism D has tension adjusting means DT for adjusting the tension of the belt T. As shown in FIG.

With this configuration, in the conveying device 1 of the present embodiment, when the belt transmission mechanism D is assembled to the intermediate link table E, it is possible to adjust the tension of the belt T and adjust the trajectory of the arm separately. This facilitates the work of attaching pulleys, etc., improves productivity, and improves the stability of belt tension and the accuracy of arm parallelism. In this embodiment, for example, after the belt transmission mechanism D is assembled to the intermediate link base E and the tension of the belt T is adjusted, the second links L2a and L2b of the second link mechanism LD2 are attached to the pulley body P2a. It becomes possible to assemble to the intermediate link base E while matching parallelism.

In the conveying device 1 of the present embodiment, the tension adjusting means DT is a pressing member P3 that is movable with respect to the intermediate link table E so that the pressing force applied to the belt T is changed.

With this configuration, the tension adjusting means DT for adjusting the tension of the belt T can be easily configured in the conveying device 1 of the present embodiment.

In the conveying device 1 of this embodiment, the tension adjusting means DT has only one pressing member P3.

Thus, in the conveying device 1 of the present embodiment, the tension of the belt T can be adjusted by pressing the belt T only at one point.

In the conveying device 1 of this embodiment, the pressing member P3 is a driven roller configured to be rotatable as the belt T moves.

As a result, in the conveying device 1 of the present embodiment, the pressing member P3 is a driven roller that rotates as the belt T moves. , the friction with the belt T is reduced, and the tension of the belt T is made uniform on both sides of the pressing member P3.

(Second embodiment)
A conveying device according to a second embodiment of the present invention will be described. The main difference between the conveying device of this embodiment and the conveying device of the first embodiment is the configuration of the belt transmission mechanism D. As shown in FIG. Therefore, the description of the configuration of the conveying apparatus of the present embodiment that is the same as that of the conveying apparatus of the first embodiment will be omitted.

The belt transmission mechanism D is, as shown in FIG. .

The intermediate connecting shaft S4b supports the rotating plate P2b, and a protruding portion N1 protruding radially outward is formed on the outer peripheral surface of the rotating plate P2b. Further, inside the intermediate link base E, on both sides of the rotary plate P2b are formed a pair of restricting portions N2 with which the projecting portions N1 come into contact when the rotary plate P2b rotates. Therefore, the rotatable range of the rotating plate P2b and the intermediate connecting shaft S4b with respect to the intermediate link base E is restricted. In this embodiment, the protrusion N1 and the pair of restricting portions N2 constitute the rotation restricting means of the present invention. That is, the belt transmission mechanism D of this embodiment differs from the belt transmission mechanism D of the first embodiment in that it has a rotation limiting means.

In FIG. 6, when the rotating plate P2b rotates clockwise with respect to the intermediate link base E, it can rotate until the projecting portion N1 comes into contact with the restricting portion N2 on the right side of FIG. When rotating counterclockwise with respect to the base E, the protrusion N1 can be rotated until it abuts against the restricting portion N2 on the left side in FIG. Therefore, the rotatable range of the second link L2b connected to the intermediate connecting shaft S4b with respect to the intermediate link base E is restricted.

That is, in the conveying device 1 of the present embodiment, the belt transmission mechanism D has rotation limiting means for limiting the rotatable range of the second link L2b with respect to the intermediate link base E. As shown in FIG.

Thus, in the conveying device 1 of the present embodiment, by limiting the range in which the second link L2b can rotate with respect to the intermediate link table E, breakage of the belt T can be prevented.

(Third Embodiment)
A conveying device according to a third embodiment of the present invention will be described. The main difference between the conveying device of this embodiment and the conveying device of the first embodiment is the configuration of the belt transmission mechanism D. As shown in FIG. Therefore, the description of the configuration of the conveying apparatus of the present embodiment that is the same as that of the conveying apparatus of the first embodiment will be omitted.

As shown in FIG. 7, the belt transmission mechanism D is incorporated inside the intermediate link base E, and has pulley bodies P1a, P1b, P2a and a belt T. As shown in FIG. That is, the belt transmission mechanism D of this embodiment differs from the belt transmission mechanism D of the first embodiment in that it does not have the pressing member P3.

In the belt transmission mechanism D, a belt T is stretched around the outer peripheral surfaces of the pulley bodies P1a, P2a, and P1b. The belt T is a steel belt, for example, and is stretched so as to follow the lower side of the outer peripheral surface of the pulley body P1a, the upper side of the outer peripheral surface of the pulley body P2a, and then the lower side of the outer peripheral surface of the pulley body P1b. stretched along the sides. Both ends of the belt T are fixed to the outer peripheral portions of the pulley bodies P1a and P1b via a plurality of bolts (not shown).

(Fourth embodiment)
A conveying device according to a fourth embodiment of the present invention will be described. The main difference between the conveying device of this embodiment and the conveying device of the first embodiment is the configuration of the belt transmission mechanism D. As shown in FIG. Therefore, the description of the configuration of the conveying apparatus of the present embodiment that is the same as that of the conveying apparatus of the first embodiment will be omitted.

The belt transmission mechanism D is, as shown in FIG. .

The pressing member P3 is supported by a shaft S5a rotatably supported by the intermediate link base E, and is composed of a driven roller rotatable as the belt T moves. The pressing member P3 presses the belt T diagonally to the upper right, and adjusts the tension of the belt T between the pulley bodies P2a and P1b. That is, the belt transmission mechanism D of this embodiment differs from the belt transmission mechanism D of the first embodiment in the direction in which the pressing member P3 presses the belt T. As shown in FIG. Therefore, the pressing member P3 moves with respect to the intermediate link base E so as to change the pressing force applied to the belt T, thereby adjusting the tension of the belt T stretched over the pulley bodies P1a, P2a, and P1b. configured as means DT.

Other configurations can also be modified in various ways without departing from the gist of the present invention.

In the above-described embodiment, a two-arm type transport apparatus having the transport units 11a and 11b has been described, but a one-arm type transport apparatus having either of the transport units 11a and 11b may be used.

In the above embodiment, in the belt transmission mechanism D, the belt T includes a pulley body P1a connected to the first link L1a, a pulley body P2a connected to the second link L2a, and a pulley connected to the first link L1b. Both ends of the belt T are fixed to the outer periphery of the pulley body P1a and the pulley body P1b. The belt T has a body P2b, and the belt T is the outer periphery of the pulley body P1a connected to the first link L1a, the pulley body P2b connected to the second link L2b, and the pulley body P1b connected to the first link L1b. Both ends of the belt T may be fixed to the outer peripheral portions of the pulley bodies P1a and P1b. Therefore, by stretching the belt T so that the pulley bodies P1a and P1b are arranged on both sides of the pulley body P2b, even when the pulley body P2b is in the released state, the belt T is stretched between the pulley bodies P1a and P1b. , the rotation of the belt T is restricted, and the pulley body P2b in the released state is prevented from rotating in the loosening direction and reducing the tension of the belt T. As shown in FIG.

In the above embodiment, the first link mechanism LD1 that connects the fixed base A as the first link base and the intermediate link base E is the first parallel four-bar link mechanism of the present invention, and the intermediate link base E and the second link base Although the case where the second link mechanism LD2 that connects the tip link plate C as the first link base and the intermediate link plate E as The first parallel four-bar link mechanism of the present invention is used as the second link mechanism LD2 that connects the A parallel four-bar link mechanism may be used.

In this case, the belt transmission mechanism D has a pulley body P2b connected to the second link L2b, and the belt T has a pulley body P2a connected to the second link L2a and a pulley body P2a connected to the first link L1a. The belt T may be stretched on the outer peripheral surfaces of the body P1a and the pulley body P2b connected to the second link L2b, and both ends of the belt T may be fixed to the outer peripheral parts of the pulley bodies P2a and P2b. . Further, the belt transmission mechanism D has a pulley body P2b connected to the second link L2b, and the belt T has a pulley body P2a connected to the second link L2a and a pulley body connected to the first link L1b. The belt T may be stretched around the outer peripheral surfaces of P1b and the pulley body P2b connected to the second link L2b, and both ends of the belt T may be fixed to the outer peripheral parts of the pulley bodies P2a and P2b.

In the above embodiment, in the belt transmission mechanism D, the pulley body P1a integrally connected to the third connecting shaft S3a, the pulley body P2a integrally connected to the fourth connecting shaft S4a, and the third connecting shaft S3b are integrally connected. The rotational driving force of the third connecting shaft S3a is transmitted to the fourth connecting shaft S4a and the third connecting shaft S3b by the pulley body P1b connected to the pulley bodies P1a, P2a, and the belt T stretched over the pulley bodies P1a, P2a, and P1b. However, when the gear integrally connected to the third connecting shaft S3a, the gear integrally connected to the fourth connecting shaft S4a, and the gear integrally connected to the third connecting shaft S3b mesh, The rotational driving force of the third connecting shaft S3a may be transmitted to the fourth connecting shaft S4a and the third connecting shaft S3b.

A fixed base (1st link base)
C tip link plate (2nd link base)
E Intermediate link base D Belt transmission mechanism DT Tension adjusting means LD1 First link mechanism (first parallel four-bar link mechanism)
L1a, L1b First link LD2 Second link mechanism (second parallel four-bar link mechanism)
L2a, L2b Second links P1a, P1b Pulley body (first pulley)
P2a pulley body (second pulley)
P3 pressing member N1 projection (rotation limiting means)
N2 regulating part (rotation limiting means)
T-belt

Claims (6)

Base end portions of a pair of first links having the same length are rotatably connected to the first link base, and tip end portions of the pair of first links are rotatably connected to the intermediate link base. A first parallel four-bar link mechanism in which any one of the first links of is rotationally driven by a driving means ;
Base ends of a pair of second links of the same length are rotatably connected to the intermediate link base, and tip ends of the pair of second links are rotatably connected to the second link base. a two-parallel four-bar linkage mechanism;
A pair of first pulleys arranged on the intermediate link base and connected to each of the pair of first links, a second pulley connected to one of the pair of second links, and both sides of the second pulley and a belt stretched so that the pair of first pulleys are arranged in a belt transmission for transmitting rotational driving force so that the first link and the second link rotate in opposite directions to each other A transport device comprising: a mechanism. 2. A conveying apparatus according to claim 1, wherein said belt transmission mechanism has tension adjusting means for adjusting the tension of said belt. 3. The conveying apparatus according to claim 2, wherein said tension adjusting means has a pressing member which is movable with respect to said intermediate link base so as to change the pressing force applied to said belt. 4. A conveying apparatus according to claim 3, wherein said tension adjusting means has only one said pressing member. 5. The conveying device according to claim 3, wherein the pressing member is a driven roller configured to be rotatable as the belt moves. 6. The belt transmission mechanism according to any one of claims 1 to 5, wherein the belt transmission mechanism has rotation limiting means for limiting a range in which the other of the pair of second links can rotate with respect to the intermediate link base. Conveyor.

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